JPS6410748B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a split type air conditioner having a function of detecting the operating state of an outdoor unit on the indoor unit side.

[Technical background of the invention and its problems]

Generally, as shown in FIG. 1, an air conditioner is a heat pump type refrigeration system that is made up of a compressor 11, a four-way valve 12, an outdoor heat exchanger 13, a capillary tube 14, and an outdoor heat exchanger 15 connected in sequence. The outdoor heat exchanger 13 is provided with an outdoor fan 16, and the indoor heat exchanger 15 is provided with an indoor fan 17. The four-way valve 12 switches the flow of refrigerant, and during cooling, it circulates the refrigerant in the direction of the solid arrow shown in the figure to form a cooling cycle, and during heating, it operates and switches the flow direction of the refrigerant to the direction of the broken arrow shown in the figure. heating cycle.

FIG. 2 shows the control circuit. Reference numeral 18 denotes an indoor unit side circuit, which is connected to the AC power supply 23. On the other hand, 1
Reference numeral 9 denotes an outdoor unit side circuit, which is connected to the power source 23 via crossover wires between the terminals 1-1 and 2-2 on the terminal boards 20 and 21. Furthermore, the circuit 18,
Terminals 3-3 on terminal boards 20 and 21 are located between 19 and 19.
An energizing line A for supplying an operation command based on the output of the power source 23 is provided between the terminals 2 and 2 via a connecting wire between the terminals 2 and 2. That is, the energizing line A is connected to the power supply 23 through the circuits 18 and 19. Therefore, in the circuit 18, there is a diode in the current carrying line A.
A series circuit of D ₁ , resistor R ₁ , thyristor SCR ₁ , and resistor R ₂ is inserted. Further, in the circuit 18, 24 is a synchronization signal generation circuit, 25 is an indoor control section, and these synchronization signal generation circuit 24 and indoor control section 25 are connected to a power source 23. The synchronization signal generation circuit 24 generates a synchronization signal corresponding to the power supply frequency. The indoor control section 25 operates in synchronization with the output of the synchronization signal generation circuit 24, and controls the operation status of the operation section 26, the room temperature sensor 27, and the indoor heat exchange sensor 28.
The thyristor ignition circuit 29 is controlled according to the detected value and the like. This thyristor ignition circuit 29 performs on/off control of the thyristor SCR ₁ , and thereby performs conduction/cutoff control of the energizing line A. In other words, the operation control command issued from the indoor control section 25 is supplied to the circuit 19 in the form of a multi-bit serial signal based on the conduction/cutoff control of the energizing line A.

On the other hand, in the circuit 19, a series circuit of a resistor R ₃ , a light emitting diode of a photocoupler PHC ₁ , and a resistor R ₄ is inserted in the current supply line A. Further, in the circuit 19, 30 is a synchronization signal generation circuit;
is an outdoor control section, and these synchronizing signal generation circuit 30 and outdoor control section 31 are connected to a power supply line based on the crossover connection of the terminal boards 20 and 21. The synchronization signal generation circuit 30 generates a synchronization signal corresponding to the power supply frequency. The outdoor control section 31 operates in synchronization with the output of the synchronization signal generation circuit 30, and generates a resistor from the phototransistor of the photocoupler PHC _1.
The switches SW ₁ and SW ₂ are controlled on and off in accordance with the signal obtained via R ₅ (operation control command from the circuit 18) and the detected value of the outdoor heat exchange sensor 32, and thereby the compressor motor 11M and It controls the supply of electricity to the four-way valve 12. Note that a photocoupler protection diode _D2 is connected in parallel to the light emitting diode of the photocoupler _PHC1 .

The operation of the above configuration will be explained using the timing chart shown in FIG. Operation unit 26
When the operating state is set, the indoor control unit 25 controls the thyristor firing circuit 29, thereby firing the thyristor SCR ₁ and issuing a set of 5-bit operation control commands (start commands) as shown in Figure b. , heating/cooling switching command, compressor control command, wait command, wait command) are sequentially transmitted to the circuit 19. Here, figure a shows the voltage waveform between terminals 1 and 2. In circuit 19,
The photocoupler PHC ₁ is driven by the conduction or interruption of the current carrying line A, and this photocoupler
The output of PHC ₁ (voltage across resistor R ₅ ) is detected by outdoor control unit 31 to obtain the data signal shown in Figure c, and controls switches SW ₁ and SW ₂ to control compressor motor 11M and four-way valve. to drive and control.

By the way, during heating operation, frost may adhere to the outdoor heat exchanger 13, so when the temperature detected by the outdoor heat exchanger sensor 32 reaches the frost adhesion temperature, the operation of the four-way valve 12 is stopped to remove the frost. Enter frost operation (cooling cycle). Circuit 1 performs this kind of defrosting operation.
Conventionally, when detecting on the 8 side, the indoor heat exchange sensor 28
defrosting operation is detected by monitoring the detected temperature.
However, with such a method, it is difficult to accurately determine defrosting operation. Therefore, in order to accurately detect the defrosting operation, it may be possible to input the detected temperature value of the outdoor heat exchanger sensor 32 to the indoor control unit 25, but this requires increasing the number of crossover wires. This results in higher costs and larger terminal boards. Further, when the operation of the compressor motor 11M is stopped in the circuit 19, the circuit 18 cannot know whether or not the operation of the compressor motor 11M has been stopped.

[Purpose of the invention]

This invention was made in view of the above-mentioned circumstances, and its purpose is to provide an excellent method for detecting the operating status of an outdoor unit without increasing the number of crossover wires connecting the indoor unit and the outdoor unit. An object of the present invention is to provide a split-type air conditioner.

[Summary of the invention]

That is _, in _this invention, in addition to the circuit configuration shown in FIG. A thyristor and a thyristor ignition circuit are inserted between the resistor R ₃ and the photocoupler PHC ₁ in the energizing line A of No. 19, and the thyristor is controlled on and off according to the operating status of the outdoor unit to make the energizing line A conductive. By performing cutoff control, the operating state of the outdoor unit is detected and determined via a photocoupler provided in the indoor unit side circuit 18.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to the drawings. Figure 4 shows its configuration.
In addition to the circuit shown in Figure 2 above, a resistor _R1 and a thyristor
A photocoupler PHC ₂ and a protective diode D ₃ are inserted at the connection point with SCR ₁ , and a resistor R ₃ is inserted in the current carrying path A of the outdoor unit side circuit 19.
Thyristor SCR ₂ between and photocoupler PHC ₁
and the above thyristor is connected to the outdoor unit side circuit and controlled by the output of the outdoor control section 31.
A thyristor firing circuit 35 is provided to control the SCR ₂ on and off.

Next, the operation of the above configuration will be explained with reference to the timing chart shown in FIG.
The circuit 18 controls the thyristor SCR ₁ on and off in synchronization with the power supply frequency, and sends an operation control command using a series signal of a 5-bit set of a start command, a cooling/heating switching command, a compressor control command, a wait command, and a weight command. 19 repeatedly. At this time, the ignition circuit 35 of the circuit 19 prepares to accept the operation control command by sequentially turning on the thyristor SCR ₂ in synchronization with the power supply frequency.
In this case, in order to ensure acceptance, the on timing of the thyristor SCR ₂ is set earlier than the on/off control timing of the thyristor SCR ₁ in the circuit 18 by τ ₀ time. Thus, during the heating operation, the circuit 18 turns on the thyristor SCR ₁ at the timing of the second bit of the operation control command, and sets the cooling/heating switching command to logic "1". Then, at that timing, the photocoupler PHC ₁ of the circuit 19 is turned on, thereby causing the circuit 19 to enter heating operation control (the four-way valve 12 is activated). In this way, if frost forms on the outdoor heat exchanger 13 during the heating operation, the outdoor control unit 31 turns off the switch SW ₂ , stops the operation of the four-way valve 12, and performs the defrosting operation (cooling operation). cycle). At this time, the outdoor control section 31
The thyristor SCR ₂ is turned off by the thyristor ignition circuit 35 at the cooling/heating switching command bit (receiving timing) of the serial signal from the circuit 18.
When the thyristor SCR ₂ turns off, the current-carrying line A is cut off and the photocoupler PHC ₂ in the circuit 18
will be turned off. Therefore, the indoor control section 2
5 is a thyristor to give a heating operation command.
It is sensed that the energizing path A is cut off even though SCR ₁ is turned on, and from this it is determined that the outdoor unit is in the defrosting operation state.

In addition, the compressor control command in the third bit of the operation control command is a logic "1" as a drive command for the compressor 11, but the outdoor control unit 31 turns off switch SW ₁ despite this drive command. When the compressor motor 11M is stopped, the outdoor control unit 31 turns off the thyristor SCR ₂ at the timing of receiving the compressor control command, thereby cutting off the energizing line A and turning off the photocoupler PHC ₂ . let Therefore, the indoor control unit 25 detects that the energization path A is cut off even though the thyristor SCR ₁ is turned on to give a compressor drive command, and the compressor 11 of the outdoor unit is thereby stopped. Determine whether the

It should be noted that the present invention is not limited to the above-mentioned embodiments, and can be applied not only to, for example, a heating/cooling switching command or a compressor control command, but also to various other commands.

〔Effect of the invention〕

As explained above, according to the present invention, a split type air conditioner is provided which has an excellent control device that can detect the operating status of an outdoor unit without increasing the number of connecting wires connecting the indoor unit side circuit and the outdoor unit side circuit. You can get a chance.

[Brief explanation of the drawing]

Figure 1 is a schematic configuration diagram of a refrigeration cycle, Figure 2 is a configuration diagram of a conventional air conditioner control circuit, and Figure 3 a.
-c are timing charts for explaining the operation of the control circuit shown in FIG. 2, FIG. 4 is a configuration diagram of the control circuit in an embodiment of the present invention, and
Figures a to e are timing charts for explaining the operation of the same embodiment. 18... Indoor unit side circuit, 19... Outdoor unit side circuit, SCR ₁ , SCR ₂ ... Thyristor,
PHC ₁ , PHC ₂ ...Photocoupler, A...Electricity line.

Claims (1)

[Claims] 1 Consists of an indoor unit and an outdoor unit that are connected to a common AC power source, each unit has an energizing line that is connected to the AC power source through each unit, and this energizing line is conducted on the indoor unit side in synchronization with the power frequency. , in a split type air conditioner that provides an operation control command from an indoor unit to an outdoor unit by a multi-bit serial signal by performing cutoff control, provided in the outdoor unit,
means for controlling conduction and cutoff of the energized line in response to the bits of the serial signal from the indoor unit and in accordance with the operating state of the outdoor unit; and a means provided in the indoor unit to detect the conduction and cutoff state of the energized line. A split type air conditioner characterized in that it comprises means for determining a plurality of operating states of the outdoor unit by comparing the detection result with conduction/cutoff control of the indoor unit.